Azacytidine-induced reactivation of a DNA repair gene in Chinese hamster ovary cells.

Six X-ray-sensitive (xrs) strains of the CHO-K1 cell line were shown to revert at a very high frequency after treatment with 5-azacytidine. This suggested that there was a methylated xrs+ gene in these strains which was structurally intact, but not expressed. The xrs strains did not complement one another, and the locus was autosomally located. In view of the frequency of their isolation and their somewhat different phenotypes, we propose that the xrs strains are mutants derived from an active wild-type gene. However, there is in addition a methylated silent gene present in the genome. Azacytidine treatment reactivated this gene. We present a model for the functional hemizygosity of mammalian cell lines, which is based on the inactivation of genes by de novo hypermethylation. In contrast to results with xrs strains, other repair-defective lines were found not to be reverted by azacytidine.     

Inducible repair of DNA single-strand breaks in gamma-irradiated Chinese hamster cells

Preirradiation of Chinese hamster cells with low-level UV-light does not influence the efficiency of repair of gamma-radiation-induced DNA single-strand breaks. With fractionated gamma-irradiation, cycloheximide delivered during the interval between the two fractions reduces the number of DNA breaks (compared to that in cells affected by the same nonfractionated dose). The data obtained indicate the presence of an inducible component of repair of DNA single-strand breaks in gamma-irradiated Chinese hamster cells.     

Chinese hamster cells exhibiting a temperature dependent alteration in purine transport

This paper reports the isolation of a phenotypically stable line of Chinese hamster ovary cells which exhibits a temperature dependent alteration in the transport of some purines. The alteration manifests itself for the uptake of guanine, hypoxanthine, azaguanine and guanosine but not for adenine, adenosine or thymidine. Studies with crude cell extracts suggest that, at the temperature the alteration is being expressed, the HGPRT activity is within the normal range. In cell-cell hybridization studies the alteration behaves as a recessive genetic trait.     

Bufalin influences the repair of X-ray-induced DNA breaks in Chinese hamster cells

The bufadienolide bufalin, a component of the Chinese medicine chan'su, has been reported to selectively inhibit the growth of various lines of human cancer cells, due at least in part to its specific effect on topoisomerase (topo) II. We have treated Chinese hamster ovary (CHO) cells with doses of bufalin that result in a dramatic reduction in both the level and catalytic activity of topo II without any concomitant induction of DNA damage, as assessed by the comet assay. When cells were pre-treated with bufalin and then irradiated with X-rays, a follow-up study revealed that the kinetics of DNA repair was clearly affected, with a general delay in the restoration of DNA to the situation observed in non-irradiated controls. The possible involvement of topo II in radiation damage repair is discussed.     

Regulation of de novo purine biosynthesis in Chinese hamster cells

Regulation of de novo purine biosynthesis was examined in two Chinese hamster cell lines, CHO and V79. De novo purine biosynthesis is inhibited at low concentrations of adenine. The mechanism of inhibition was studied using the RNA and protein synthesis inhibitors actinomycin D, cycloheximide, and azacytidine. Although all three inhibitors rapidly inhibited de novo purine biosynthesis in vivo, neither adenine nor the RNA and protein synthesis inhibitors could be found to have an effect in vitro on either phosphoribosylpyrophosphate (PRPP) synthetase or amido phosphoribosyltransferase, the first enzymes of the de novo pathway. However, in the presence of actinomycin D, cycloheximide, and azacytidine, there was a 50% or greater reduction in PRPP concentrations. This reduction in PRPP levels is correlated with a 2-fold increase in purine nucleotides in the acid-soluble pool. It is proposed that in the presence of the metabolic inhibitors there is an increase in nucleotide pools due to degradation of RNA, with a resulting feedback inhibition on de novo purine biosynthesis. In contrast to a previous report (Martin, D. W., Jr., and Owen, N. T. (1972) J. Biol. Chem. 247, 5477-5485), we could find no evidence for a repressor type mechanism in these cells.     

Metal-induced DNA damage and repair in human diploid fibroblasts and Chinese hamster ovary cells

Cloning efficiency and DNA strand breaks induction were compared in human diploid fibroblasts (HSBP) and chinese hamster ovary (CHO) cells treated with various metal salts. Cadmium (Cd2+), nickel (Ni2+) and chromate (Cr2O7) reduced the cloning efficiency of HSBP cells more than that of CHO cells whereas the reverse was true after treatment with mercury (Hg2+), manganese (Mn2+) and cobalt (Co2+). The effects on cloning efficiency did not consistently correlate with DNA strand breaking activity as all metals except Cr(VI) were more effective at producing DNA strand breaks in CHO cells than in human cells. The differential responses of the two cell types was shown to be only partially due to differences in cellular uptake of metals. DNA breaks induced in human cells by Hg2+ and Cr2O7 were shown most likely to be alkaline labile sites rather than true strand breaks since no damage was detected in a nick translation assay which measures the amount of free 3'-OH terminals. Damage induced by Mn2+ and Co2+, however, appeared to be comprised at least in part by true DNA strand breaks. DNA damage was also induced in HSBP cells following treatment with selenium but only in the presence of reduced glutathione. These studies indicate that DNA damage is not as major a consequence following some metal treatments in human cells as it appears to be in rodent cells. This suggests that rodent models for risk estimation of metal-induced tumorigenesis may not always be appropriate for extrapolation to humans.     

Defect in the caffeine-dependent postreplication DNA repair in UV-sensitive Chinese hamster clone cells

The postreplication repair of DNA in the presence of caffeine was investigated in the Chinese hamster clones cells of different UV-sensitivity. Caffeine (10(-2)M) inhibits the repair of daughter DNA (PRR of DNA) in the UV-light irradiated cells of UV-resistant clones CHO-K1, 14-2C-1 and V79, but does not influence the PRR of DNA in cells of UV-sensitive clones CHS1 and CHS2. Thus, deficiency of PRR of DNA in cells of UV-sensitive clones (the repair of daughter DNA is significantly retarded) is associated with the defect of the caffeine-dependent component of this repair process.     

Characterization of a DNA repair domain containing the dihydrofolate reductase gene in Chinese hamster ovary cells

The formation and removal of UV-induced pyrimidine dimers were measured in restriction fragments near and within the essential dihydrofolate reductase (DHFR) gene in Chinese hamster ovary cells in order to map the genomic fine structure of DNA repair. Dimer frequencies were determined at 0, 8, and 24 h after irradiating the cells with 20 J/m2 UV light (254 nm). Within 8 h, the cells had removed more than 40% of the dimers from sequences near the 5' end of the gene, somewhat fewer from the 3' end, but only 2% from the 3' flanking region and 10% from a region upstream from the gene. The corresponding extent of repair in the genome as a whole is 5-10% in the 8-h period. Isoschizomeric restriction enzyme analysis was used to detect the level of methylation in the fragments in which repair was measured. We found that the only hypomethylated sites in and around the DHFR gene were in the fragment near its 5' end, which displayed maximal DNA repair efficiency. The size of the region of preferential DNA repair at the DHFR locus appears to be in the range of 50-80 kilobases, and this finding is discussed in relation to genomic domains and the structure of mammalian chromatin.     

Alkylation damage, DNA repair and mutagenesis in human cells

17 human cell lines that differ significantly in level of O⁶-alkylguanine-DNA alkyltransferase (AGT) activity were identified by comparing their sensitivity to the cytotoxic effect of N-methyl-N′-nitro-N-nitrosoguanidine (MNNG) and determining the level of AGT activity in cell extracts from the various lines by measuring the decrease in radiolabeled O⁶-methylguanine from DNA, using high-performance liquid chromatography. 9 lines exhibited high levels of AGT activity, 2 showed an intermediate level (25–50% of the mean of those with the higher levels), and 6 exhibited very low or virtually undetectable levels of AGT. Included were several lines that are very deficient in capacity for nucleotide excision repair. When representatives from the 3 categories of cell lines defined by the level of AGT activity were compared for sensitivity to the cytotoxic and mutagenic effect of MNNG, they showed an inverse correlation between the degree of cell killing and frequency of mutants induced and the level of AGT activity. The cells' capacity for nucleotide excision repair did not affect these results. Exposure of cells with a high level of AGT activity to O⁶-methylguanine in the medium reduced the AGT activity 60–80%. These pre-treated cells exhibited a significantly higher frequency of MNNG-induced mutants than did cells that were not pre-treated, suggesting that the O⁶-methylguanine lesion in DNA is responsible for a significant proportion of the mutations induced. Cell strains containing substrates for assaying intrachromosomal homologous recombination were constructed using parental cell lines from each of the 3 categories of AGT activity. These strains showed an inverse correlation between the level of AGT activity and the frequency of MNNG-induced recombination. When various cell lines representing the 3 categories of AGT activity were compared for sensitivity to ethylnitrosourea, the results were consistent with AGT and nucleotide excision repair playing a role in preventing cell killing and mutation induction by this agent.     

Inhibition of repair of UV-damaged DNA by caffeine and mutation induction in Chinese hamster cells

The effect of caffeine on UV-irradiated Chinese hamster cells in vitro was studied on the cellular and molecular levels. Caffeine (1 mM) was shown to decrease the colony-forming ability and the frequencies of spontaneous and UV-induced mutations in Chinese hamster cells. The effect of caffeine in reducing the frequency of UV-induced mutations was demonstrated only if caffeine was present in the culture medium during the first post-irradiation cell division. Using alkaline sucrose gradient centrifugation, both parental and newly synthesized DNA in UV-irradiated and unirradiated cells were studied in the presence and absence of caffeine. Caffeine affected the sedimentation profile of DNA synthesized in UV-irradiated cells but not in unirradiated cells. Caffeine had no apparent effect on the incorporation of [³H]-thymidine into DNA of control or UV-irradiated cells, nor on the small amount of excision of UV-induced pyrimidine dimers. These results may be interpreted by a hypothesis that caffeine inhibits a certain S-phase specific, post-replication, dark-repair mechanism. The hamster and perhaps other rodent cells exposed to low doses of UV are capable of DNA replication, by-passing the non-excised pyrimidine dimers. This postulated repair process probably involves de novo DNA synthesis to seal the gaps in the nascent strand. This repair may be also responsible for the enzymatic production of mutations.     

Decreased DNA repair capacity of UV-irradiated cells following interferon treatment

The aim of this study was to examine the effect of interferons (IFNs) on the recovery of UV-damaged cells by means of measuring cell viability rates. The influence of the recombinant human interferons IFN-alpha, IFN-beta and IFN-gamma on the repair capacity of the UV-irradiated human cell lines WISH and HeLa was studied. The ability of cells to repair UV-induced damage was determined by the comet assay and both short- and long-term survival assays in proliferating cell cultures. We found that INFs negatively regulated DNA repair in cells damaged by UV light. One day after treatment, in both cell lines tested, IFN-alpha had a stronger inhibitory effect than IFN-gamma. Combined treatment with different IFNs exhibited a stronger inhibitory effect on cell recovery than treatment with each of them. The protein kinase inhibitor wortmanin further aggravated the effect of IFNs on cell survival.     

Cycloheximide resistance in Chinese hamster cells I. Spontaneous mutagenesis

Resistance to cycloheximide (CHM) was studied in cultured Chinese hamster cells. Concentrations of CHM above 5.10⁻⁷M were toxic for the cells. At concentrations above 9.10⁻⁷M no colonies were recovered in selective medium. 15 resistant clones of independent origin were isolated in selective medium containing 7.10⁻⁷M CHM. Resistance was stable when the cells were cultured under non-selective conditions. The spontaneously mutation rate was determined by the fluctuation test. Mutations to CHM resistance arose spontaneously. The spontaneous mutation rate to CHM resistance was about 10⁻⁵.     

Gene amplification in Chinese hamster DNA repair deficient mutants

In order to study the possible relationship between gene amplification and DNA repair we analyzed the amplification of the CAD gene in four mutants hypersensitive to UV light (CHO43RO, CHO7PV, UV5 and UV61) isolated in vitro from Chinese hamster cell lines (CHO-K1 and AA8). These mutants are characterized by different defects in the nucleotide excision repair mechanism and represent complementation groups 1, 9, 2, and 6 respectively. To evaluate the amplification ability of each cell line we measured the rate of appearance of PALA resistant clones with the Luria and Delbrück fluctuation test. Resistance to PALA is mainly due to amplification of the CAD gene. In the mutants CHO43RO, UV5 and CHO7PV we reproducibly found an amplification rate lower than in the parental cell lines (2–5 times), while in UV61 the amplification rate was about 4 times higher. This result indicates that each mutant is characterized by a specific amplification ability and that the unefficient removal of UV induced DNA damage can be associated with either a higher or a lower amplification rate. However, the analysis of randomly isolated CHO-K1 clones with normal UV sensitivity has shown variability in their amplification ability, making it difficult to relate the specific amplification ability of the mutants to the DNA repair defect and suggesting clonal heterogeneity of the parental population.